Tension–Compression Flow Asymmetry as a Function of Alloy Composition in the Al-Si System
Microelectromechanical system for in situ quantitative testing of tension–compression asymmetry in nanostructures - Nanoscale Horizons (RSC Publishing) DOI:10.1039/D3NH00407D
Schematic showing the size-dependent strength trend of a-Si pillars
Jun DING, Doctor of Philosophy, Lawrence Berkeley National Laboratory, CA, LBL, Materials Sciences Division
The atomistic deformation mechanism of Li 0.5 Si under the uniaxial
Microelectromechanical system for in situ quantitative testing of tension–compression asymmetry in nanostructures - Nanoscale Horizons (RSC Publishing) DOI:10.1039/D3NH00407D
Metals, Free Full-Text
Anomalous tension–compression asymmetry in amorphous silicon: insights from atomistic simulations and elastoplastic constitutive modeling - ScienceDirect
PDF) Significant “smaller is softer” in amorphous silicon via irradiation-mediated surface modification
Investigation on the Tension–Compression Asymmetry of CoCrFeNiAl High-Entropy Alloy Under the Influence of Twinning Boundary Spacing
Anomalous tension–compression asymmetry in amorphous silicon: insights from atomistic simulations and elastoplastic constitutive modeling - ScienceDirect
Anomalous tension–compression asymmetry in amorphous silicon: insights from atomistic simulations and elastoplastic constitutive modeling - ScienceDirect
a Schematic of the evolution of the biaxial stress in an a- Si thin fi
Microscopic mechanisms of pressure-induced amorphous-amorphous transitions and crystallisation in silicon